Log in
The National Space Centre (NSC), sited in the Abbey Meadows area of the City of Leicester, combines elements of museum and visitor attraction with an educational mission to attract 8-14 year olds to the Science, Technology, Engineering and Mathematics (STEM) subjects using the inspiration of space science and exploration. Since its opening on June 30th 2001, the NSC has welcomed almost 2.5 million visitors to its galleries and full-dome planetarium. Space science research within the UoA was a driving force in the establishment of the NSC and continues to contribute to its success. Members of the Unit serve as non-executive Directors on the NSC Operating Company (OPCO) Board and as Trustees, while others contribute to its Space Now public outreach programme and to the Space Academy teacher engagement project which began in the East Midlands region, but now has national scope. The claimed impact is not only related to outreach and quantitative educational outcomes, but also to long-term economic benefit to the City of Leicester, through the regeneration of a brownfield site in a disadvantaged inner-city district, now featuring the development of a science park with the National Space Centre as its focus.
UCL's research and development programme in space science and engineering enabled it to complete four major contracts with European and Canadian space companies between 2009 and 2011. These contracts were for the supply of equipment that will fly on European and Indian space missions, and for support of the ground testing of those space missions. The fact that these contracts were won by UCL in a competitive environment against low-cost industrial providers demonstrates that customers value the capability that UCL possesses. By acting as a specialist provider within the UK space sector supply chain, UCL enabled the prime contractors European Astrium Aerospace and Canadian Routes AstroEngineering Ltd. to deliver substantial commercial contracts with space agencies. Its provision of specialist input into these major contracts enabled UCL to also directly support the growth of the commercial space sector.
The University of Southampton's distinguished body of work on the design of technology for gamma-ray detection and imaging has informed new counter-terrorism practices. Technological advances arising from the research have been crucial to delivering significant benefits in the fields of homeland security and nuclear safety — the latter particularly in the wake of the 2011 Fukushima disaster. A spin-out company, Symetrica, currently employs 26 people in the UK and the USA, has a forecast turnover of more than £10 million for 2013-14 and has been recognised as an example of best practice. It is a technological leader in the field of radioactive isotope identification.
Research conducted within the Department of Space and Climate Physics at UCL has had a significant impact upon e2v Ltd., a manufacturer of charge-coupled devices (CCDs). Through working collaboratively with e2v, UCL has helped the company to secure major contracts and business [text removed for publication]. This includes two contracts for the supply of CCDs for the European Space Agency (ESA) missions Gaia (€20 million) and Euclid (€10 million). Furthermore, the symbiotic relationship has contributed to the establishment of e2v as Europe's leading supplier of high-quality CCDs for space science applications and has underpinned an improved understanding of device design and optimisation within the company.
Space science and medicine share a fundamental requirement for radiation sensors of the highest possible sensitivity. The development of imaging detectors for major X-ray observatories such as the European XMM-Newton and NASA's Chandra provided the impetus for a broad-based, intensive programme of deliberate technology transfer from the Unit's Space Research Centre (SRC) into the life sciences and medicine. The resulting impact now extends far beyond the exploratory provision of prototype sensor technologies for biomedical researchers into the full-scale commercial exploitation of those technologies with industry partners in the UK and Europe and, in three separate cases, to early-stage patient trials. Impact is being delivered in clinical specialisms from oncology to ophthalmology; from neurotoxicology to emergency medicine. The impact delivery mechanisms — the hospital-based Diagnostics Development Unit (DDU) and the campus-based Bioimaging Unit — are themselves novel and have achieved national prominence as examples of best practice in the drive for economic return even from established blue skies research.
The university's Bayfordbury Observatory is a working observatory that engages with the public via six Open Evenings and approximately 50 group visits a year, offering access to a wide range of facilities. Many of the 4,000 visitors annually report that they develop a first or renewed `enthusiasm for astronomy', or become `inspired to learn more' about what they have seen or heard from our researchers; some young people enthuse about `now wanting to be a scientist'. Science teachers taking an RCUK `cutting-edge' CPD astrophysics course also say that they have gained an `increased understanding of the subject', and `increased confidence in its delivery to pupils'.
The Space & Atmospheric Physics (SPAT) group's magnetometer laboratory at Imperial has developed a small and lightweight magnetic field instrument intended to be flown on future generations of extremely small satellites or planetary landers. The instrument will be used for planetary research or plasma physics in the space environment, and also has application for attitude determination on satellites in Earth-orbit, by comparison with the geomagnetic field (`digital compass'). In 2010 Imperial Innovations granted Satellite Services Ltd (now the SSBV Aerospace and Technology Group) an exclusive 3-year license to market the design for the commercial satellite sector. Satellite Services have sold seven units (circa. € 10,000 per unit) with further commercial sales anticipated in the coming years. Sales of the device have contributed significantly to SSBV's company turnover, indicating the economic impact of the SPAT group's research.
Research on Frequency Selective Surface (FSS) structures has led to major advances in the design and manufacture of the world's most advanced payload instrumentation for use in Earth observation satellites. This technology has provided the core element of the radiometer instrumentation needed for more accurate global weather forecasts and better understanding of climate change. The advances described have made it possible to combine all of the different functions of the MetOP-SG radiometer into one instrument, thereby halving the footprint of the satellite payload resulting in a [text removed for publication] cost saving.
The Space Robotics unit is heavily involved with the ESA/Roscosmos 2018 ExoMars rover mission, and is responsible for the radiometric and colourimetric calibration and image processing for two of the ExoMars science cameras during mission operations. Camera emulators have been built which has led to novel hyperspectral camera technology being developed. A terrestrial aerial version of this camera has been deployed in an unmanned aerial system (UAS) used for advanced remote sensing for precision agriculture applications. Impact on practitioners in this application area has emerged together with economic impact via Welsh Government funding. The ExoMars related research has led to impact in the area of society, culture and creativity.
Maple is a major commercial computer algebra system, with millions of users worldwide. It is used in many industrial applications, covering diverse sectors including automotive, aerospace and defense, electronics, energy, financial services, consumer products, entertainment, basic research and teaching. Research by Davenport's team at Bath, in collaboration with the University of Western Ontario, has led to algorithmic advances that have been incorporated in recent releases of Maple. These advances mean that Maple can solve systems of equations it could not previously solve, give completely accurate solutions to systems it could previously only approximate, and can present the solutions to the user in an improved manner.
As well as including code written at Bath directly in Maple, MapleSoft have deployed a Senior Developer to integrate the work of Davenport's team closely into the Maple system. These solution algorithms are now transparently available to all users of Maple. MapleSoft themselves have used the solution algorithms in an industrial application in a consultancy project with a major Japanese automotive manufacturer.